On the methodology of calculating volume charge density in a MIFGMOS substrate using Poisson’s equation

IF 0.7 4区工程技术 Q4 ENGINEERING, ELECTRICAL & ELECTRONIC

Microelectronics International Pub Date : 2021-10-14 DOI:10.1108/mi-01-2021-0004

Francisco Javier Plascencia Jauregui, A. M. Medina Vázquez, Edwin Christian Becerra Álvarez, José Manuel Arce Zavala, Sandra Fabiola Flores Ruiz

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引用次数: 0

Abstract

Purpose This study aims to present a mathematical method based on Poisson’s equation to calculate the voltage and volume charge density formed in the substrate under the floating gate area of a multiple-input floating-gate metal-oxide semiconductor metal-oxide semiconductor (MOS) transistor. Design/methodology/approach Based on this method, the authors calculate electric fields and electric potentials from the charges generated when voltages are applied to the control gates (CG). This technique allows us to consider cases when the floating gate has any trapped charge generated during the manufacturing process. Moreover, the authors introduce a mathematical function to describe the potential behavior through the substrate. From the resultant electric field, the authors compute the volume charge density at different depths. Findings The authors generate some three-dimensional graphics to show the volume charge density behavior, which allows us to predict regions in which the volume charge density tends to increase. This will be determined by the voltages on terminals, which reveal the relationship between CG and volume charge density and will allow us to analyze some superior-order phenomena. Originality/value The procedure presented here and based on coordinates has not been reported before, and it is an aid to generate a model of the device and to build simulation tools in an analog design environment.

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用泊松方程计算MIFGMOS衬底中体积电荷密度的方法

目的本研究旨在提出一种基于泊松方程的数学方法来计算多输入浮栅金属氧化物半导体金属氧化物半导体（MOS）晶体管的浮栅区域下衬底中形成的电压和体积电荷密度。设计/方法/方法基于该方法，作者根据向控制门（CG）施加电压时产生的电荷来计算电场和电势。这种技术使我们能够考虑浮栅在制造过程中产生任何捕获电荷的情况。此外，作者还引入了一个数学函数来描述通过衬底的电势行为。根据产生的电场，作者计算了不同深度的体积电荷密度。发现作者生成了一些三维图形来显示体积电荷密度的行为，这使我们能够预测体积电荷密度趋于增加的区域。这将由端子上的电压决定，这揭示了CG和体积电荷密度之间的关系，并将使我们能够分析一些高阶现象。独创性/价值本文介绍的基于坐标的程序以前从未报道过，它有助于生成设备模型并在模拟设计环境中构建模拟工具。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Microelectronics International 工程技术-材料科学：综合

CiteScore

1.90

自引率

9.10%

发文量

审稿时长

>12 weeks

期刊介绍： Microelectronics International provides an authoritative, international and independent forum for the critical evaluation and dissemination of research and development, applications, processes and current practices relating to advanced packaging, micro-circuit engineering, interconnection, semiconductor technology and systems engineering. It represents a current, comprehensive and practical information tool. The Editor, Dr John Atkinson, welcomes contributions to the journal including technical papers, research papers, case studies and review papers for publication. Please view the Author Guidelines for further details. Microelectronics International comprises a multi-disciplinary study of the key technologies and related issues associated with the design, manufacture, assembly and various applications of miniaturized electronic devices and advanced packages. Among the broad range of topics covered are: • Advanced packaging • Ceramics • Chip attachment • Chip on board (COB) • Chip scale packaging • Flexible substrates • MEMS • Micro-circuit technology • Microelectronic materials • Multichip modules (MCMs) • Organic/polymer electronics • Printed electronics • Semiconductor technology • Solid state sensors • Thermal management • Thick/thin film technology • Wafer scale processing.